Battery-powered hand-guided power tool

ABSTRACT

A battery powered, hand guided power tool, such as a hammer, includes a tool housing  3  that contains an electric motor M, a grip portion  2  and a rail-and-channel structure  36,37,54,55  for releasable mounting of a rechargeable battery pack  50.  A locking device is provided on the tool housing  3  and includes a latch element  18,19  which is movable into a latch recess  52,53  formed in a housing of the battery pack  50,  whereby the battery pack is locked in an operative position on the tool housing, movable by a user, against the force of a spring  20,21.  The latch element  18,19  can be pivoted by a user to extract the latch element from the latch recess  52,53  for the release of the battery pack  50  from assembly with the tool housing  3.  On the tool housing  3  adjacent to the rail-and-channel structure  36,37,54,55,  there is provided a frame part  15  that includes at least one frame-part recess  16,17.  The latch element  18,19  and the associated spring  20,21  are introduced into the frame-part recess  16,17  from an open side thereof. An operating element  22,23,  in the form of a two-armed lever, is pivotally mounted laterally of the frame-part recess  16,17,  where one arm  24,25  of the lever is accessible for pivoting by the user and the other arm  26,27  is in engagement with the latch element  18,19  to facilitate displacement of the latch element from the locking position. Also, the operating element  22,23  supports the latch element  18,19  from being displaced completely from the frame-part recess  16,17.

BACKGROUND OF THE INVENTION

This invention relates to a battery-powered, hand-guided power tool, and in particular to a hammer formed with structure for the releasable mounting of a rechargeable battery pack with the hammer, and a locking device for locking the battery pack in its operative position with the hammer.

A power tool, such as a drilling hammer, is disclosed in German Patent Publication No. DE 195 21 423 (A1) and includes a tool housing. The tool further includes a rail-and-channel structure which is formed on a side portion of the tool housing and extends on a front side of a portion of the housing. The tool housing is also formed with a rear hand grip substantially at right angles to a longitudinal axis of a tool holder supported at the front of the tool. A spring-loaded latch element is located in a lower part of the hand grip, which, when in a locking position and with a battery housing assembled with the tool housing, engages in a latch recess of the battery housing to thus hold the battery pack in its operative position on the tool housing. The latch element is accessible through an opening at the lower end of the hand grip, so that a user may move the latch element, manually against the force of a compression spring, out of the locking position and into a release position.

The hand grip of the hammer disclosed in the above-noted German Publication No. DE 195 21 423 is formed with an opening for the user's hand, but is not structured for ergonomic comfort. Also, it appears that it would be virtually impossible to hold and support the battery pack in one hand, to prevent the pack from falling, while moving the latch element into its release position with the same hand.

The drilling hammer, as disclosed in German Publication No. DE 195 21 423, includes a first half-shell and a second half-shell which, when assembled, form the tool housing for supporting therein various components of the hammer. Prior to assembly of the first and second half-shells, the compression spring and the latch element are located within an inner portion of the first half shell, and are securely held in place when the first and second half-shells are assembled. With this structure, it is necessary that a support be formed in one of the half-shells to support the latch element. If there is no battery pack assembled with the tool housing, the support prevents the latch element from being pressed by the compression spring completely out of an opening through which the latch element is positioned to engage the ultimately inserted battery pack. Although this awkward mounting of the spring and the latch element in a tool housing formed by two half shells is possible, such an assembly is not possible when the tool housing, or that part of the tool housing that receives the latch element, is in the form of a one-piece barrel type housing.

SUMMARY OF THE INVENTION

Therefore, it is an object of this invention to provide a power tool having a latch structure which is simple to construct and is easily mounted during assembly of the components of the power tool.

With this and other objects in mind, this invention contemplates a battery-powered, hand-guided power tool having structure for the releasable mounting of a battery pack, which includes a tool housing having a gripping portion. A rail-and-channel structure is provided for the releasable mounting of the battery pack with the tool housing upon relative movement between the battery pack and the tool housing in a prescribed direction. A locking device is located on the tool housing and includes at least one latch element movable, in a direction substantially perpendicular to the prescribed direction, into a latch recess formed in a housing of the battery pack in a locking position in which the battery pack is locked in an operative position on the tool housing. A frame part is located on the tool housing and is formed with a frame-part recess adjacent the rail-and-channel structure for receipt of the at least one latch element in the locking position. A biasing element is located on the tool housing for normally urging the at least one latch element in a direction away from the frame-part recess. An operating element in the form of a lever is mounted for pivotal movement relative to the tool housing, and has a first arm formed on the lever which is accessible for pivoting movement thereof by a user. A second arm is formed on the lever and is in engagement with the at least one latch element for enabling the at least one latch element to be moved, upon movement of the first arm, between battery-pack locking and release positions. The operating element supports the latch element from being displaced completely from the frame-part recess.

Other objects, features and advantages of the present invention will become more fully apparent from the following detailed description of the preferred embodiment, the appended claims and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings:

FIG. 1 is side view showing a drilling hammer with battery pack located in its operative position in accordance with certain principles of the invention;

FIG. 2 is a partial perspective view showing a battery pack in assembly with parts of the drilling hammer of FIG. 1 in accordance with certain principles of the invention;

FIG. 3 is a sectional view taken along line III—III of FIG. 1 through tool housing of the drilling hammer, but with the omission of the parts of motor and gear structure normally present in this region, in accordance with certain principles of the invention;

FIG. 4 is an exploded perspective view showing the tool housing, with parts to be assembled therewith, and the battery pack, in accordance with certain principles of the invention;

FIG. 5 is an exploded perspective view showing the tool housing, with parts to be assembled therewith, in accordance with certain principles of the invention;

FIG. 6 is a partial perspective view showing a portion of one half shell of a grip housing of the drilling hammer od FIG. 1, a half shell of the housing of the battery pack used and parts of the motor housing in accordance with certain principles of the invention;

FIG. 7 is a partial perspective view showing the engagement of the tool-side contacts and the battery-side contacts when the battery pack is locked in its operative position according to certain principles of the invention;

FIG. 8 is a side view showing the drilling hammer of FIG. 1 with an unlocked battery pack;

FIG. 9 is a partial perspective view, corresponding to FIG. 2, showing the battery pack unlocked;

FIG. 10 is a partial perspective view, corresponding to FIG. 6, showing the battery pack unlocked; and

FIG. 11 is a partial perspective view, corresponding to FIG. 7, showing the position of the tool-side contacts and the battery-side contacts with the battery pack unlocked.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

A power tool, such as a drilling hammer illustrated in FIG. 1, has a tool housing 3, which includes a barrel-like motor housing 1, open towards a rear end, and further includes, at the rear end, a grip housing 2 formed by two half-shells (one shown). An electric motor M and a pneumatic hammer mechanism (not shown) are normally located in the tool housing 3. A tool holder 7 is fixed in the customary manner on a spindle, not shown) at a front end of the drilling hammer. A hammer bit (not shown), can be inserted in the tool holder 7 and, in the operation customary for drilling hammers, is loaded by impacts from the hammer mechanism and/or is rotatably driven.

The grip housing 2 forms a grip opening 4, into which a switch actuator 5 for activating the electric motor extends. The motor is powered by a battery pack 50, which is detachably secured to the drilling hammer in a manner to be described hereinafter.

As shown in FIGS. 3, 4 and 5, the motor housing 1 has an integrally formed frame part 15 on its underside, which at its rear region has integrally formed connecting sleeves 14 and in its front region has two frame-part recesses 16, 17 that are separated by a transverse wall that lies in the central plane 43 (FIG. 3) of the tool housing 3, wherein a longitudinal axis 6 of the tool housing coincides with an axis of rotation of the tool holder 7.

Compression springs 20, 21 and latch elements 18, 19 are inserted into respective ones of the frame-part recesses 16, 17, which are in the form of blind bores. In the outer side walls of the recesses 16, 17 there are respective slit shaped through openings 44, 45. Into each of these through openings 44,45 extends an inner arm 26, 27 respectively of an operating element 22, 23, respectively, which operating element is in the form of a substantially L shaped two armed lever and, formed integrally therewith, is a respective front pivot pin 28, 29 and a respective rear pivot pin 30, 31. The pivot pins 26, 28 and 29, 31 are snapped into front and rear bearing sleeves 32, 34 and 33, 35 respectively, integrally formed with the frame part 15 and open towards the outside, so that the operating element 22, 23 is pivotally mounted on the frame part.

Secured laterally to the frame 15 are covers 8, 9, which have a respective through opening 10, 11 into which the respective outer arm 24, 25 of the respective operating element 22, 23 extends, so that the outer face of that arm 24, 25 is accessible from the outside of the covers. The covers 8, 9 have inwardly projecting, internally threaded connecting sockets 12, 13, which in the mounted state extend into the connecting sleeves 14. By means of screws (not shown), internal threads of the connecting sockets 12,13, the covers 8, 9 are releasably held on the frame part 15, and they cover in particular the pivot pins 28, 30, and 29, 31 of the operating elements 22, 23, respectively, and the associated bearing sleeves 32, 34 and 33, 35, respectively, and constitute a visual downward continuation of the motor housing 1.

It will be noted that, by means of this construction, the latch elements 18, 19 can be very easily mounted and held within the recesses 16, 17. If the spring 20,21 and the associated latch element 18,19 is inserted into the frame-part recess 16,17, then, with the latch element fixedly held, the inner arm 26, 27 of the associated operating element 22, 23 is pushed through the respective slit shaped through opening 44, 45 in the side wall of the respective recess 16, 17 and into a lateral slit shaped opening 18 a, 19 a of the respective latch element 18, 19. This arrangement prevents the compression spring 20, 21 from being able to push its associated latch element 18, 19 out of the recess 16, 17, respectively. The pivot pins 28, 30 and 29, 31 of the operating element 22, 23, respectively, are snapped into the bearing sleeves 32, 34 and 33, 35 respectively, so that the operating elements 22, 23 are positioned in the position shown in FIG. 3 for the operating element 23. As assembled, the compression spring 20 (FIG. 4), presses the latch element 19 downward toward the battery pack 50 and against the inner arm 27 of the operating element 23 as the arm extends into the opening in the latch element 19, so that the operating element 23 is biassed, causing it to pivot clockwise. This pivoting movement is limited by contact of the inner arm 27 against the lower edge of the slit shaped through opening 45 provided in the frame part 15, that is, the latch element 19 is able to protrude downwards out of the recess 17 only as far as the lowered latched position illustrated in FIG. 3. The same applies to the latch element 18, not illustrated in FIG. 3, which is inserted in the recess 16 and cooperates with the operating element 22.

At their lower ends, the covers 8, 9 form inwardly projecting rails 36, 37 which extend at least approximately parallel to the longitudinal axis 6, and which serve as guide and retaining rails for assembling and mounting the battery pack 50. The battery pack 50 is formed with channels 54, 55 of complementary form to the rails 36,37, and are open at the rear end. This allows the front ends of the rails 36, 37 to enter the channels 54, 55 and the battery pack 50 to be pushed along the rails to an end position in which, as shown in FIGS. 1 and 2, the rear wall of the battery pack lies against a front surface formed by the two half shells of the grip housing 2. The latch elements 18,19 are formed with wedge-shaped surfaces 18 b, 19 b at their lower ends. As the battery pack 50 is assembled with the tool housing 3, upper surfaces of each of the latch elements 18,19 engage and compress the compression springs 20,21, fully into the recesses 16, 17. In the fully mounted position of the battery pack 50, as shown in FIG. 6, the latch elements 18, 19 snap into latch recesses 52, 53 formed in an upper surface of the battery pack and lock the battery pack against forward displacement from this operative or fully mounted position. In this manner, the rails 36,37 and the channels 54,55, respectively, form a rail-and-channel structure of the drilling hammer for releasably mounting the battery pack 50 with the hammer.

As shown in FIGS. 2, 6, 7, 9, 10 and 11, a plurality of tool contacts 42 are attached to the motor housing 1, and are electrically connected via connections to the different components within the tool housing 3. The tool contacts 42 are arranged in a frame which opens towards the front. A corresponding plurality of battery contacts 51 are located on the upper side of the battery pack 50 in the rear region thereof, and are mounted in a frame which is open at the rear. In the position shown in FIGS. 2, 6 and 7, that is, the locked or operative position of the battery pack 50, the battery contacts 51 are in electrical conducting engagement with the tool contacts 42.

As shown in FIG. 6, an aperture 40 is formed in an upper end region of the bearing surface of the tool housing 3, which is a bearing surface for the rear end face of the battery pack 50. A generally thimble shaped cap 39 extends into the aperture 40, and has at its rear end an outwardly directed shoulder, the external diameter of which is larger than the diameter of the aperture 40, so that the cap 39 is unable to escape from the housing through the aperture 40. The cap 39 is biassed by a helical spring 38, which is located on a supporting pin 41 (FIG. 10) formed integrally with the wall of the grip housing 2 opposite the aperture 40. The helical spring 38 bears against this wall of the grip housing 2 to effect a forward displacement of the cap 39, that is, to effect a displacement towards a position in which the shoulder of the cap 39 bears against the wall region surrounding the aperture 40. As shown in FIG. 6, with the battery pack 50 inserted and located in the locked or operative position, the cap 39 is pushed as far as possible into the tool housing 3 with the helical spring 38 fully compressed.

In order to separate the battery pack 50 in its operative position from the drilling hammer, a user grips the covers 8, 9 and the front region of the battery pack 50 with one hand from the front, and presses inward, for instance with a thumb and forefinger, the outer arms 24, 25 of the operating elements 22 and 23. This causes the operating elements 22,23 to pivot about their pivot pins 28, 30 and 29, 31, respectively, whereby the latch elements 18, 19 are lifted, against the force of the compression springs 20, 21, that is, they are moved further into the recesses 16, 17, until the lower ends of the latch elements 18, 19 are retracted from the latch recesses 52, 53 of the battery pack 50. As the latch elements 18, 19 release the battery pack 50, the battery pack is urged by the force of the helical spring 38, which presses the cap 39 against the battery pack, forwardly along the rails 36, 37. A slight displacement of the battery pack 50 is sufficient to ensure that the latch elements 18, 19 do not re-enter the latch recesses 52, 53 of the battery pack 50 after the operating elements 22, 23 have been released. Instead the latch elements 18,19 abut the upper surface of the battery pack 50. The helical spring 38 not only effects the slight displacement of the battery pack 50, but on release or retraction of the latch elements 18, 19, the helical spring 38 also urges the battery pack such a distance along the rails 36 and 37 for a distance sufficient to safely disengage the battery contacts 51 from the tool contacts 42.

Accordingly, the displacement of the battery pack 50 by the helical spring 38 effects not only a mechanical disengagement of the battery pack, but also causes the electrical connection between the battery pack and the drilling hammer to be safety interrupted. For that purpose, the spring 38 has a restoring force that is greater than the weight of the battery pack 50, so that a corresponding displacement of the battery pack can be reliably effected. Thus, even when the user unlocks the battery pack 50 with the tool holder 7 of the power tool pointed upward the battery pack is moved by the spring 38 against gravity along the vertically positioned rails 36, 37. Moreover, the travel of the spring 38 between the fully compressed position (FIG. 6) and the position in which the outwardly directed shoulder of the cap 39 is supported against the wall region of the tool housing 3 surrounding the aperture 40 (FIG. 10), is greater than the length over which the battery contacts 51 in the operative position of the battery pack 50 shown in FIGS. 1, 2 and 6 are in engagement with the tool contacts 42. As the latch elements 18, 19 are displaced from the locked position shown in FIG. 6 into the release position shown in FIG. 10, in any orientation of the power tool the spring 38 reliably effects a displacement of the battery pack 50 along the rails 36, 37, such that a separation of the battery contacts 51 and the tool contacts 42 is effected.

For the rest, the travel of the spring 38 between the fully compressed position (FIG. 6) and the position shown in FIG. 10, in which the outwardly directed shoulder of the cap 39 rests against the wall region surrounding the aperture 40, should not be so large that the battery pack 50 is moved into a position in which it is no longer reliably held on the rails 36, 37, but is virtually “shot out” of its mounting on the rails. It is therefore advantageous if the travel of the spring 38 is no greater than half the length of the battery pack 50 in the region of the rail and channel structure 36, 37, 54, 55 in the direction of the longitudinal extent of the channels 54, 55, so that, in the state displaced by the spring 38, the battery pack still rests on at least half the longitudinal extent of the rails 36, 37.

When the user inserts the battery pack 50 into the drilling hammer, the user has to displace the cap 39 a distance sufficient to compress the spring 38 to move the battery pack into the position in which the latch elements 18, 19 lock into the latch recesses 52, 53 of the battery pack. In that position, the battery contacts 51 are then also electrically connected to the tool contacts 42. If, however, the user fails to push in the battery pack 50 until the latch elements 18,19 lock in, on being released the battery pack will be displaced by the action of the spring 38 into the position shown in FIGS. 8 and 10, so that this error is obvious to the user. Moreover, there is no chance whatsoever that the battery pack 50 can be electrically connected with the drilling hammer and can set this in operation when the battery pack is not locked in its operative position by engagement of the latch elements 18, 19.

In general, the above-identified embodiments are not to be construed as limiting the breadth of the present invention. Modifications, and other alternative constructions, will be apparent which are within the spirit and scope of the invention as defined in the appended claims. 

What is claimed is:
 1. A battery-powered, hand-guided power tool having structure for the releasable mounting of a battery pack, which comprises: a tool housing which includes a gripping portion; a rail-and-channel structure for the releasable mounting of the battery pack with the tool housing upon relative movement between the battery pack and the tool housing in a prescribed direction; a locking device located on the tool housing; the locking device including at least one latch element movable, in a direction substantially perpendicular to the prescribed direction, into a latch recess formed in a housing of the battery pack in a locking position in which the battery pack is locked in an operative position on the tool housing; a frame part located on the tool housing; a frame-part recess formed in the frame part adjacent the rail-and-channel structure for receipt of the at least one latch element in the locking position; a biasing element located on the tool housing for normally urging the at least one latch element in a direction away from the frame-part recess; an operating element in the form of a lever mounted for pivotal movement relative to the tool housing; a first arm formed on the lever which is accessible for pivoting movement thereof by a user; a second arm formed on the lever which is in engagement with the at least one latch element for enabling the at least one latch element to be moved, upon movement of the first arm, between battery-pack locking and release positions; and the operating element supporting the latch element from being displaced completely from the frame-part recess.
 2. A power tool according to claim 1, wherein the operating element is in the form of an L-shaped lever.
 3. A power tool according to claim 1 wherein the second arm of the operating element extends through a slit-shaped opening in a wall of the latch recess.
 4. A power tool according to claim 1, wherein the second arm of the operating element extends into a laterally open engagement aperture in the latch element.
 5. A power tool according to claim 1, wherein a pivot axis of the operating element is formed by two pivot pins, that are snapped into bearing sleeves provided on the tool housing.
 6. A power tool according to claim 1, wherein a pivot axis of the operating element is formed by two pivot pins, that are snapped into bearing sleeves provided on the tool housing and the bearing sleeves are open on their side remote from the recess.
 7. A power tool according to claim 1, wherein the biasing element is a compression spring located between an inner end of the latch element and a floor of the latch recess.
 8. A power tool according to claim 1, wherein a cover is fastened laterally to the tool housing and has a through opening through which the first arm of the operating element is accessible.
 9. A power tool according to claim 1, wherein a cover is fastened laterally to the tool housing and has a through opening through which the first arm of the operating element is accessible and the cover forms a part of the rail-and-channel structure.
 10. A power tool according to claim 1, which includes two latch elements located in adjacent recesses and each latch element has an associated operating element located such that the first arms of the operating elements are located on opposite sides of the tool housing.
 11. A power tool according to claim 1, which further comprises: a tool holder mounted on a forward end of the tool housing along a longitudinal axis of the tool housing and the tool holder; the rail-and-channel structure extending at least approximately parallel to the longitudinal axis; the grip portion of the tool housing extending in a direction away from the longitudinal axis adjacent a rear end of the tool housing; and a tool-housing part of the rail-and-channel structure located adjacent and forward of the grip portion. 